There are two types of continuous-wave radar:
unmodulated continuous-wave and
modulated continuous-wave.
Unmodulated continuous-wave This kind of radar can cost less than $10 (2021). Return frequencies are shifted away from the transmitted frequency based on the
Doppler effect when objects are moving. There is no way to evaluate distance. This type of radar is typically used with competition sports, like golf, tennis, baseball,
NASCAR racing, and some smart-home appliances including light-bulbs and motion sensors. The Doppler frequency change depends on the
speed of light in the air (
c’ ≈ c/1.0003 is slightly slower than in vacuum) and the speed of the target
v: :f_r = f_t \left( \frac{1+v/c'}{1-v/c'} \right) The Doppler frequency is thus: :f_d = f_r-f_t = 2v \frac {f_t}{c'-v} Since the usual variation of targets' speed of a radar is much smaller than c', (v \ll c'), it is possible to simplify with c'-v \approx c' : :f_d \approx 2v \frac {f_t}{c'} Continuous-wave radar without frequency modulation (FM) only detects moving targets, as stationary targets (along the
line of sight) will not cause a Doppler shift. Reflected signals from stationary and slow-moving objects are masked by the transmit signal, which overwhelms reflections from slow-moving objects during normal operation.
Modulated continuous-wave Frequency-modulated continuous-wave radar (FM-CW)also called continuous-wave frequency-modulated (CWFM) radar is short-range measuring radar capable of determining distance. This increases reliability by providing distance measurement along with speed measurement, which is essential when there is more than one source of reflection arriving at the radar antenna. This kind of radar is often used as "
radar altimeter" to measure the exact height during the landing procedure of aircraft. It is also used as early-warning radar,
wave radar, and proximity sensors. Doppler shift is not always required for detection when FM is used. While early implementations, such as the APN-1 Radar Altimeter of the 1940s, were designed for short ranges, Over The Horizon Radars (OTHR) such as the Jindalee Operational Radar Network (JORN) are designed to survey intercontinental distances of some thousands of kilometres. In this system the transmitted signal of a known stable frequency
continuous wave varies up and down in frequency over a fixed period of time by a modulating signal. Frequency difference between the receive signal and the transmit signal increases with delay, and hence with distance. This smears out, or blurs, the Doppler signal. Echoes from a target are then mixed with the transmitted signal to produce a
beat signal which will give the distance of the target after demodulation. A variety of modulations are possible, the transmitter frequency can slew up and down as follows: •
Sine wave, like air raid siren •
Sawtooth wave, like the chirp from a bird •
Triangle wave, like police siren in the United States •
Square wave, like police siren in the United Kingdom Range demodulation is limited to a quarter wavelength of the transmit modulation. Instrumented range for 100 Hz FM would be 500 km. That limit depends upon the type of modulation and demodulation. The following generally applies. :\text{Instrumented Range} = F_r-F_t = \frac {\text{Speed of Light}}{(4 \times \text{Modulation Frequency})} The radar will report incorrect distance for reflections from distances beyond the instrumented range, such as from the moon. FMCW range measurements are only reliable to about 60% of the instrumented range, or about 300 km for 100 Hz FM.
Sawtooth frequency modulation Sawtooth modulation is the most used in FM-CW radars where range is desired for objects that lack rotating parts. Range information is mixed with the Doppler velocity using this technique. Modulation can be turned off on alternate scans to identify velocity using unmodulated carrier frequency shift. This allows range and velocity to be found with one radar set. Triangle wave modulation can be used to achieve the same goal. As shown in the figure, the received waveform (green) is simply a delayed replica of the transmitted waveform (red). The transmitted frequency is used to down-convert the receive signal to
baseband, and the amount of frequency shift between the transmit signal and the reflected signal increases with time delay (distance). The time delay is thus a measure of the range; a small frequency spread is produced by nearby reflections, a larger frequency spread corresponds with more time delay and a longer range. With the advent of modern electronics,
digital signal processing is used for most detection processing. The beat signals are passed through an
analog-to-digital converter, and digital processing is performed on the result. The transmit signal x(t) of a saw-tooth FM-CW radar consists of one or multiple ramps (see figure). A single ramp starts with a frequency f_0 and increases linearly with slope \alpha. :f(t) = f_0 + \alpha t, The ramp ends after a duration T and has covered a bandwidth B = \alpha T. During the time of a single ramp, the transmit signal is a scaled cosine. : x(t) = a_\mathrm{tx} \cos \left( \phi(t) \right) = a_\mathrm{tx} \cdot \cos \left( 2 \pi \left[f_0 + \frac{\alpha}{2}t \right] t \right) The instantaneous frequency is \frac{1}{2 \pi}\cdot \frac{\mathrm{d} \phi(t)}{\mathrm{d} t} = f(t) The radar receives the signal y(t) which is a sum of K damped and delayed versions of the signal x(t). :: y(t) = \sum_{k=0}^{K-1} b_k x(t - \tau_k) The delays \tau_k denote the time a signal travels form the radar to an object and back to the radar. This time depends on the initial distance between the radar r and the object at time t=0, on the relative velocity v, and on the
speed of light in the medium (with c'=c/n and n=1 in vacuum and n=1.0003 for air) :: \tau_k = \frac{2 r}{c'} - \frac{2 v}{c'} t The radar mixes (multiplies) the received signal y(t) with the transmitted signal x(t) and applies a low-pass filter. The resulting ″deramped″ signal can be approximated as a sum of cosines. :: y_\mathrm{deramped}(t) \approx \sum_{k=0}^{K-1} a_\mathrm{tx} b_k \cos\left( 2 \pi f_{\mathrm b,k} t + \varphi_k \right) Each of these cosines corresponds to a path that the signal travelled from the radar to an object and back to the radar. The frequencies f_{\mathrm b,k} are called
beat frequencies. :: f_{\mathrm{b},k} = \frac{2 \alpha r_k}{c'} - \frac{2 v_k f_\mathrm{c}}{c'}, The beat frequencies depend on the distance (range) r_k between radar and object k, on the speed of light, on the slope \alpha, the relative velocity v_k of object k with respect to the radar, and on the carrier frequency f_\mathrm{c} = f_0 + B/2. Since the beat frequency contains the distance r_k to the object and the velocity v_k of the object, it is in general not possible to separate both quantities from a single transmitted saw-tooth only. If the velocity is zero or if v f_\mathrm{c} is negligible compared to \alpha r_k, the distance can be computed via ::r_k = \frac{c' f_{\mathrm{b},k}}{2 \alpha}. As described above, the deramped signal is a superposition of cosines. This results in an inherent ambiguity in the distance estimation (now assuming non-moving objects). According to the
Nyquist–Shannon sampling theorem, the maximum frequency that can be recovered after sampling is half the sampling frequency f_\mathrm S. Hence, the maximum beat frequency that can be observed after sampling is f_{\mathrm b, \mathrm{max}} = f_\mathrm S / 2. This translates into maximum range r_\mathrm{max}. This ambiguity is called the
maximum unambiguous range. :: r_\mathrm{max} = \frac{f_\mathrm{S} c'}{4 \alpha} = \frac{f_\mathrm{S} c' T}{4 B} The maximum unambiguous range depends on the sampling frequency f_\mathrm{S}, on the speed of light c', and on the frequency slope \alpha (or equivalently on the length T of the saw-tooth and the covered bandwidth B). Without any additional information, an FM-CW radar with saw-tooth frequency modulation cannot distinguish between a distance r and a distance r' = r + n r_\mathrm{max}, for any integer n. Both distances would result in the same beat frequency. Usually, it is just assumed that only ranges r = 0 \ldots r_\mathrm{max} are present. For practical reasons, receive samples are not processed for a brief period after the modulation ramp begins because incoming reflections will have modulation from the previous modulation cycle. This imposes a range limit and limits performance. ::\text{Range Limit} = 0.5 \ c' \ t_{radar} ,
Sinusoidal frequency modulation Sinusoidal FM is used when both range and velocity are required simultaneously for complex objects with multiple moving parts like turbine fan blades, helicopter blades, or propellers. This processing reduces the effect of complex spectra modulation produced by rotating parts that introduce errors into range measurement process. This technique also has the advantage that the receiver never needs to stop processing incoming signals because the modulation waveform is continuous with no impulse modulation. Sinusoidal FM is eliminated by the receiver for close in reflections because the transmit frequency will be the same as the frequency being reflected back into the receiver. The spectrum for more distant objects will contain more modulation. The amount of spectrum spreading caused by modulation riding on the receive signal is proportional to the distance to the reflecting object. The time domain formula for FM is: : y(t) = \cos \left\{ 2 \pi [ f_{c} + \Beta \cos \left( 2 \pi f_{m} t \right) ] t \right\}\, ::where \Beta = \frac{f_{\Delta}}{f_{m}} (modulation index) A time delay is introduced in transit between the radar and the reflector. : y(t) = \cos \left\{ 2 \pi [ f_{c} + \Beta \cos \left( 2 \pi f_{m} (t + \delta t) \right) ] (t + \delta t) \right\}\, ::where \delta t = time delay The detection process down converts the receive signal using the transmit signal. This eliminates the carrier. : y(t) = \cos \left\{ 2 \pi [ f_{c} + \Beta \cos \left( 2 \pi f_{m} (t + \delta t) \right) ] (t + \delta t) \right\}\;\cos \left\{ 2 \pi [ f_{c} + \Beta \cos \left( 2 \pi f_{m} t \right) ] t \right\}\, : y(t) \approx \cos \left\{ -4 t \pi \Beta \sin ( 2 \pi f_{m} (2t + \delta t) \sin ( \pi f_{m} \delta t) + 2 \delta t \pi \Beta \cos (2 \pi f_{m} ( t + \delta t) ) \right\}\, The
Carson bandwidth rule can be seen in this equation, and that is a close approximation to identify the amount of spread placed on the receive spectrum: :\text{Modulation Spectrum Spread} \approx 2 (\Beta + 1 ) f_m \sin (\delta t ) :\text{Range} = 0.5 C / \delta t Receiver demodulation is used with FMCW similar to the receiver demodulation strategy used with pulse compression. This takes place before
Doppler CFAR detection processing. A large modulation index is needed for practical reasons. Practical systems introduce reverse FM on the receive signal using digital signal processing before the
fast Fourier transform process is used to produce the spectrum. This is repeated with several different demodulation values. Range is found by identifying the receive spectrum where width is minimum. Practical systems also process receive samples for several cycles of the FM in order to reduce the influence of sampling artifacts. == Configurations ==